N-calcium channel knockout animal

ABSTRACT

A non-human animal in which a gene coding for the N-type calcium channel is disrupted to lack functional N-type calcium channel, and a method for screening for a substance having a pharmacological action on blood pressure control, transmission of pain, blood sugar level control and so forth by using the animal.

This application is the U.S. National Phase under 35 U.S.C. §371 of International Application PCT/JP00/07503, filed Oct. 26, 2000, which claims priority to Japanese Patent Application No. 11-303809, filed Oct. 26, 1999, Japanese Patent Application No. 2000-37839, filed Feb. 16, 2000, and Japanese Patent Application No. 2000-261979, filed Aug. 31, 2000. The International Application was not published under PCT Article 21(2) in English.

TECHNICAL FIELD

The present invention relates to an animal deficient in N-type calcium channel and use thereof.

BACKGROUND ART

Calcium channels (Ca channels) are membrane proteins that transmit information into cells by controlling influx of Ca²⁺ into the cells. In particular, voltage-dependent Ca channels present in excitatory cells such as nerve cells and muscle cells are proteins that play an important role of converting information transmitted through changes in membrane potential, into intracellular information which is an increase in Ca²⁺ concentration.

Various voltage-dependent Ca channels have been identified from nerve cells and muscle cells (Bean, B. P. et al, Ann. Rev. Physiol., 51, pp. 367–384, 1989; Ross P., Ann. Rev. Neurosci., 56, p. 337, 1990), and these are classified into six types (L, N, P, Q, R and T) according to their electrophysiological properties and susceptibility to antagonists.

Among these Ca channels, N-type Ca channel is a Ca channel characterized in that Ca²⁺ influx is inhibited by a peptide toxin isolated from cone shell, ω-conotoxin GVIA.

Calcium antagonists are widely used as antianginal drugs, antiarrhythmic drugs and therapeutic agents for hypertension, and their action mechanism is based on relaxation of vascular smooth muscles or suppression of myocardial contraction by inhibition of the Ca²⁺ influx into a cell through a specific binding to the L-type Ca channel present in a cell membrane. Meanwhile, it is being revealed that Ca²⁺ is an important factor for normal functions in nerves, such as release of nerve transmitter substances, formation of impulse patterns and outgrowth of neurites, while a Ca²⁺ kinetics change is deeply involved in diseases such as delayed nerve cell death after cerebral ischemia and a certain kind of epilepsy (Siesjo, Mayo Clin Proc., 61, p. 299, 1986). Over the last few years, existence of P-, N-, Q- and R-type Ca channels, which are specifically present in nerves, were confirmed in addition to L-type and T-type. Roles of these Ca channels in nervous functions draw attentions, and novel calcium antagonists targeting them are being actively developed at the same time.

In particular, it has been reported that the N-type Ca channel is expressed at nerve endings of the autonomic nervous system, and its role in control through autonomic nerves is attracting attentions (Lane D. H. et al., Science, 239, pp. 57–61, 1988; Diane L, et al., Nature, 340, pp. 639–642, 1989).

Functions of the N-type Ca channel have hitherto been evaluated by conducting 1) an in vitro experiment using synaptosomes or cultured nerve cells or 2) an in vivo experiment using administration of ω-conotoxin GVIA. Since 1) is an in vitro experiment, it is not suitable for precise evaluation of the N-type Ca channel functions in living bodies. On the other hand, although 2) is an in vivo experiment, this is not suitable for precise evaluation of the N-type Ca channel functions in living bodies either because (1) selectivity of ω-conotoxin GVIA has not been completely elucidated, (2) ω-conotoxin GVIA is a peptide and hence it does not have sufficient permeability to a nerve cell, (3) a chronic-stage experiment using administration of ω-conotoxin GVIA is difficult and so forth.

DISCLOSURE OF THE INVENTION

In order to overcome the aforementioned drawbacks, preparation of an N-type Ca channel knockout mouse that is deficient only in the N-type Ca channel and can be used for a chronic-stage experiment has been strongly desired.

Accordingly, an object of the present invention is to prepare a knockout mouse which lacks α_(1B) subunit of the N-type Ca channel (referred to as “N-KO mouse” hereinafter). By using such a mouse, what functions the N-type Ca channel is actually responsible for in living bodies can be elucidated, which N-type Ca channel is considered to be expressed at nerve terminals of the central nervous system and the peripheral nervous system and plays an important role in maintenance of homeostasis of living bodies.

The N-KO mouse may not be able to maintain homeostasis through the autonomic nervous system, especially it cannot control blood pressure, and hence it may not survive normally. However, it was considered that, even though the N-KO mouse could not survive normally, the N-type Ca channel functions could be deduced from abnormalities observed in the N-KO mouse. Thus, it was attempted to prepare an N-KO mouse in which a gene coding for the α_(1B) subunit of the N-type Ca channel was disrupted by targeted disruption.

As a result, it was revealed that the N-KO mouse could undergo ontogenesis and growth and could produce offspring. Moreover, it was electrophysiologically proved that Ca²⁺ influx that is inhibited by ω-conotoxin GVIA was not observed in nerve cells in dorsal root ganglia prepared from the N-KO mouse, and hence it was confirmed that the N-KO mouse lacked functional N-type Ca channel.

As a result of further studies, it was also revealed that the N-KO mouse had characteristics unique to deficiency in N-type Ca channel such as no blood-pressure reflex through nervous systems, insensitity to pain and low blood sugar level compared with a wild-type mouse, and that the N-KO mouse was useful for analysis of N-type Ca channel functions in living bodies. Thus, the present invention has been accomplished.

That is, the present invention provides a non-human animal in which a gene coding for an N-type Ca channel is disrupted to lack functional N-type Ca channel (hereinafter, also referred to as “animal of the present invention”). The non-human animal is preferably a rodent, more preferably a mouse.

The gene coding for the N-type Ca channel is preferably a gene coding for an α_(1B) subunit of the N-type Ca channel. More specifically, there can be mentioned a gene comprising DNA defined in the following (a) or (b):

(a) DNA which comprises the nucleotide sequence of SEQ ID NO: 1;

(b) DNA which is hybridizable with DNA comprising the nucleotide sequence of SEQ ID NO: 1 under a stringent condition and codes for an α_(1B) subunit of functional N-type calcium channel.

The present invention also provides a method for determining an action of a substance, which comprises steps of administering a substance to the animal of the present invention and determining an action of the substance on the animal (hereafter, also referred to as “the determination method of the present invention”).

The determination method of the present invention preferably comprises steps of administering a substance to the animal of the present invention and a wild-type animal, and comparing actions of the substance on the animal of the present invention and the wild-type animal to determine the action of the substance on the N-type calcium channel.

The present invention further provides a method for screening for a substance having a pharmacological action, which comprises a step of determining a pharmacological action of a substance by the determination method of the present invention, a substance having a pharmacological action obtained by this screening method and a method for manufacturing a drug, which comprises steps of screening for a substance having a pharmacological action by the screening method and manufacturing a drug comprising the obtained substance as an active ingredient.

As the pharmacological action, there can be mentioned an action for lowering blood pressure, an analgesic action and an action for lowering blood sugar level. Substances having such pharmacological actions can be used to manufacture hypotensive drugs, analgesic drugs and hypoglycemic drugs comprising these substances as active ingredients, respectively.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a restriction enzyme map of a phage DNA clone and pBS59/63/58n.

FIG. 2 shows preparation of a targeting vector.

FIG. 3 shows preparation of a targeting vector.

FIG. 4 shows preparation of a targeting vector.

FIG. 5 shows comparison of electric currents passed through N-type Ca channels of an N-KO mouse and a wild-type mouse.

FIG. 6 shows comparison of heart rate and blood pressure of an N-KO mouse and those of a wild-type mouse.

FIG. 7 shows comparison of changes in blood pressure of an N-KO mouse and a wild-type mouse, to ω-conotoxin was administered.

FIG. 8 shows comparison of changes in blood pressure of an N-KO mouse and a wild-type mouse, which were subjected to bilateral carotid occlusion (BCO).

FIG. 9 shows comparison of susceptibilities of an N-KO mouse and a wild-type mouse to pain in a formalin test.

FIG. 10 shows comparison of blood sugar levels of an N-KO mouse and a wild-type mouse.

FIG. 11 shows comparison of blood sugar levels of an N-KO mouse and a wild-type mouse after glucose administration.

FIG. 12 shows comparison of blood insulin level of an N-KO mouse and a wild-type mouse after glucose administration.

FIG. 13 shows comparison of autonomic innervation for atrial cardiac muscle contractile forces in an N-KO mouse and a wild-type mouse.

BEST MODE FOR CARRYING OUT THE INVENTION

Hereafter, embodiments of the present invention will be explained in detail.

As described above, the inventors of the present invention found that a mouse deficient in functional N-type Ca channel underwent ontogenesis and growth and could produce offspring, and that this mouse was useful for analysis of N-type Ca channel functions in living bodies. The animal of the present invention is based on these findings and is characterized by being a non-human animal wherein a gene coding for the N-type Ca channel is disrupted to lack functional N-type Ca channel.

Disruption of a gene means introducing a mutation into the gene so that function of its gene product is lost. As a method for disrupting a gene, there can be mentioned targeted disruption. The targeted disruption is a method for disrupting a gene by gene targeting, and refers to a mutation introducing technique wherein DNA having a nucleotide sequence of a target gene into which a mutation by which function of the gene product is lost is introduced, preferably DNA having a nucleotide sequence of a target gene into which a selective marker, more preferably a drug resistance gene is inserted, so that function of the gene product is lost, is introduced into a cell, and a cell having undergone homologous recombination between the introduced DNA and the target gene is selected (Suzanne L. et al., Nature, 336, p. 348, 1988). The targeted disruption mentioned herein is an example of a technique for disrupting the gene coding for an N-type Ca channel based on information about the nucleotide sequence of the gene, and any techniques fall within the scope of the present invention so long as a gene is disrupted based on information about the nucleotide sequence thereof.

Further, lack of a functional N-type Ca channel means that there is no longer substantial influx of Ca²⁺ passed through the N-type Ca channel and can be verified by absence of substantial influx of Ca²⁺ inhibited by ω-conotoxin GVIA. The ω-conotoxin GVIA referred to herein is a peptide purified from cone shell (Conus geographus) toxin (Baldomero, M. O. et al., Biochemistry, 23, p. 5087, 1984), and it is characterized by the amino acid sequence of SEQ ID NO: 3.

A gene coding for an N-type Ca channel means a gene coding for a constitutional subunit contained only in the N-type Ca channel, for example, the α_(1B) subunit.

Specific examples of the gene coding for the α_(1B) subunit include a gene having DNA defined in the following (a) or (b): (a) DNA which comprises the nucleotide sequence of SEQ ID NO: 1;

(b) DNA which is hybridizable with DNA comprising the nucleotide sequence of SEQ ID NO: 1 under a stringent condition and codes for the α_(1B) subunit of a functional N-type calcium channel.

An example of the stringent condition mentioned herein include the conditions of hybridization at 65° C. in 4×SSC and subsequent washing at 65° C. in 0.1×SSC for 1 hour. The stringent condition may alternatively be 42° C., 4×SSC in 50% formamide.

The non-human animal is preferably a rodent, more preferably a mouse.

The animal of the present invention can be prepared according to a usual method for preparing a knockout animal by gene targeting except that the gene coding for an N-type Ca channel is used as a target gene.

Hereafter, cloning of the N-type Ca channel α_(1B) subunit gene, construction of a targeting vector used in targeted disruption and acquisition of an embryonic stem cell (ES cell) having undergone homologous recombination will be explained in this order by exemplifying targeted disruption of a gene coding for an N-type Ca channel.

1. Cloning of DNA Including Part of N-type Ca Channel α_(1B) Subunit Gene

DNA coding for the N-type Ca channel α_(1B) subunit can be obtained by designing primers based on the nucleotide sequence described in Thlerry, C. et al., FEES Letters, 338, p. 1, 1994 and performing PCR using non-human animal genomic DNA or cDNA or performing RT-PCR using non-human animal RNA. Alternatively, a probe may be synthesized based on the nucleotide sequence described in the aforementioned reference, and clones hybridizable with the probe may be selected from a non-human animal genomic DNA library or cDNA library and determined for the nucleotide sequences to select a clone containing the N-type Ca channel α_(1B) subunit gene or a part thereof comprising a nucleotide sequence of preferably 500 bp or more, more preferably 1 kbp or more.

A restriction enzyme map is prepared by determining restriction enzyme sites contained in the cloned DNA. In the case where a clone containing DNA of a length enough to cause homologous recombination, i.e., a clone of preferably 7 kbp or longer, more preferably 10 kbp or longer, is not obtained, DNAs may be excised from a plurality of clones at appropriate restriction enzyme sites and ligated.

2. Construction of Targeting Vector

A positive selection marker such as a drug resistance gene, preferably a neomycin resistance gene, is introduced into a restriction enzyme site of an exon region in the obtained DNA having a length enough to cause homologous recombination. Further, a part of the exon may be eliminated and replaced with a drug resistance gene. When there is no appropriate restriction enzyme site, appropriate restriction enzyme sites may be introduced by PCR using a primer designed so as to include restriction enzyme sites, ligation of oligonucleotides including restriction enzyme sites and so forth.

Preferably, the vector includes a negative selection marker such as thymidine kinase gene and diphtheria toxin gene in order to eliminate ES cells that do not undergo homologous recombination between the introduced DNA and the N-type Ca channel α_(1B) subunit gene in which the introduced DNA is inserted into a site that is not the N-type Ca channel α_(1B) subunit gene.

These recombinant DNA techniques for manipulating DNA nucleotide sequences can be implemented according to, for example, the methods described in Sambruck, J., Fritsch, E. F., and Maniatis, T., “Molecular Cloning: A Laboratory Manual”, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y., 1989, but such techniques are not limited to these methods so long as appropriate recombinant DNA can be obtained.

3. Acquisition of Embryonic Stem Cell (ES Cell) Having Undergone Homologous Recombination

The prepared targeting vector is digested with restriction enzymes to form linear DNA, purified by, for example, phenol/chloroform extraction, agarose electrophoresis, ultracentrifugation and so forth and transfected into an ES cell, for example, TT2. Examples of the transfection method include electroporation, lipofection and so forth, but the present invention is not limited to these methods.

The transfected cell is cultured in an appropriate selection medium, for example, a selection medium containing neomycin and ganciclovir when a targeting vector incorporated with a neomycin resistance gene and a thymidine kinase gene is constructed.

It is readily confirmed by PCR or the like that an introduced gene, for example, a neomycin resistance gene, is incorporated into an ES cell that shows resistance to the both drugs and grows. Further, occurrence of the homologous recombination can also be confirmed by Southern blotting analysis using a 5′ upstream or 3′ downstream part of DNA outside the targeting vector as a probe. Further, it can be confirmed by Southern blotting analysis using DNA with the targeting vector as a probe that the targeting vector is not randomly inserted. An ES cell having undergone homologous recombination can be obtained by combining these methods.

An example of a method for preparing a knockout mouse will be described below, but the present invention is not limited to this example.

A knockout mouse is prepared by taking steps of collection of an 8-cell embryo or a blastocyst after fertilization, microinjection of an ES cell having undergone homologous recombination, implantation of a manipulated egg into a pseudopregnant mouse, delivery from the pseudopregnant mouse and raising of offspring, selection of a transgenic mouse by PCR and Southern blotting, and establishment of pedigree of mice having the introduced gene (Yagi, T. et al., Analytical Biochem., 214, p. 70, 1993).

1. Collection of 8-Cell Embryo or Blastocyst

As for fertilized eggs, 5 IU of pregnant mare's serum gonadotropin and 2.5 IU of human chorionic gonadotropin are intraperitoneally administered to a female mouse in order to induce superovulation, and an 8-cell embryo is obtained from the female mouse on day 2.5 after fertilization by the oviduct-uterus perfusion method. When a blastocyst is used, the uterus of a female mouse is removed on day 3.5 after fertilization and an embryo is obtained by uterus perfusion.

2. Microinjection of ES Cell Having Undergone Homologous Recombination

An ES cell having undergone homologous recombination is microinjected into the obtained 8-cell embryo or blastocyst. The microinjection can be performed under an inverted microscope by using a micromanipulator, microinjector, injection pipette and holding pipette based on, for example, the descriptions in Hogan, B. L. M., “A laboratory Manual”, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y., 1986 (Yagi, T. et al., Analytical Biochem., 214, p. 70, 1993). Further, as an injection dish, for example, there are used 5-μl medium droplets and droplets containing floating ES cells formed on Falcon 3002 (Becton Dickinson Labware), on which liquid paraffin is overlaid. Hereinafter, an 8-cell embryo or blastocyst microinjected with an ES cell having undergone homologous recombination is referred to as a manipulated egg.

3. Implantation of Manipulated Egg into Pseudopregnant Mouse

A vasoligated male mouse and a normal female mouse are mated to prepare a pseudopregnant mouse, into which a manipulated egg is implanted. Implantation of a manipulated egg can be performed based on, for example, the descriptions in Hogan, B. L. M., “A laboratory Manual”, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y., 1986 and Yagi, T. et al., Analytical Biochem., 214, P. 70, 1993. An example of specific procedure will be described below, but the present invention is not limited to this example.

A pseudopregnant mouse is generally anesthetized by using, for example, 50 mg/kg body weight of pentobarbital sodium. Then, both flanks are incised about 1 cm to expose the ovary and the oviduct. The bursa ovarica is incised by using tweezers under a stereoscopic microscope to expose the fimbriae tubae. Subsequently, 7 to 8 manipulated eggs per oviduct are introduced into the fimbriae tubae. At this time, implantation of the manipulated eggs into the oviduct is confirmed by micro air bubbles inserted together with the manipulated eggs. Then, the oviduct and the ovary are returned to the abdominal cavity, both of the incision sites are sutured, and the mouse is awakened from the anesthesia. In some cases, manipulated eggs may be cultured until the following day to be developed into a blastocyst and then implanted into the uterus.

4. Delivery from Pseudopregnant Mouse and Raising of Offspring

In many cases, offspring mice can be obtained on day 17 after the implantation. The offspring mice are usually chimeric mice obtained from the ES cell having undergone homologous recombination and a cell of the mouse from which the fertilized egg is collected. For example, when TT2 is used as an ES cell and injected into an 8-cell embryo collected from ICR, an offspring mouse having a high chimeric rate shows an agouti-dominant coat color, while a mouse having a low chimeric rate shows a white-dominant coat color.

5. Screening for Gene-Introduced Mouse by PCR and Southern Blotting

Whether the gene is present in a germ cell can be readily confirmed by the coat color of an offspring mouse obtained by mating a mouse of interest with a mouse having a white coat color, for example, ICR. Alternatively, since a mouse having a high chimeric rate is expected to also have a germ cell containing the introduced gene, the presence or absence of the gene can be confirmed by using a mouse having a chimeric rate as high as possible for mating, extracting DNA from the tail of the obtained offspring mouse and subjecting its DNA to PCR. Further, a genotype can be more reliably identified by performing Southern blotting analysis instead of PCR.

6. Establishment of Lineage of Mice Having Introduced Gene

An N-KO mouse in which the introduced gene homozygously exists can be obtained among the offspring mice obtained by mating heterozygous mice (hereinafter, referred to as He mice) with each other. The N-KO mouse can be obtained by mating He mice with each other, a He mouse with an N-KO mouse, or N-KO mice with each other.

The presence or absence of expression of the α_(1B) subunit mRNA in the N-KO mouse can be confirmed by Northern blotting analysis, RT-PCR, RNase protection assay, in situ hybridization or the like. Further, expression of the α_(1B) subunit protein can be confirmed by immunohistochemical staining, labeled ω-conotoxin or the like. Further, a function of an N-type Ca channel including the α_(1B) subunit can also be confirmed by an electrophysiological method or the like.

Moreover, as described above, the inventors of the present invention found that an animal lacking the gene coding for an N-type Ca channel lost blood pressure control through the autonomic nervous system, had defects in a mechanism for transmitting pain, especially second phase pain that appears in a delayed manner, and had abnormality in blood sugar level control. That is, they found that the animal had unique characteristics associated with the deletion of the gene coding for an N-type Ca channel. The determination method of the present invention is based on these findings and it is a method for determining an action of a substance that comprises steps of administering a substance such as a compound to the animal of the present invention and determining the action of the substance on the animal.

The determination method of the present invention preferably comprises steps of administering a substance to the animal of the present invention and a wild-type animal and comparing actions of the substance on the animal of the present invention and the wild-type animal to determine the action of the substance on the N-type Ca channel. The influence of the substance on the N-type Ca channel can be examined by determining the action on the N-type Ca channel.

An action refers to an action on a characteristic unique to the animal. For example, when attention is paid to abnormality of the animal in blood pressure control, transmission of pain or blood sugar level control, the action refers to an action on the blood pressure, pain or blood sugar level. However, the action is not limited to these examples so long as the action is associated with the characteristics unique to the animal. These actions can be determined as activities of the substances.

Further, a wild type means that functional N-type Ca channel is not lost.

The present invention further provides a method for screening for a substance having a pharmacological action by using the animal of the present invention (non-human animal deficient in N-type Ca channel). Specifically, a method for screening for a substance having a pharmacological action, for example, a substance acting on blood pressure, transmission of pain or blood sugar level of the animal (that is, a substance having an action for lowering blood pressure, a substance having an analgesic action or a substance having an action for lowering blood sugar level) by using the determination method of the present invention, a substance obtained by the screening and a method for manufacturing a drug that comprises steps of screening for a substance having a pharmacological action by using the determination method of the present invention and manufacturing a drug (for example, hypotensive drug, analgesic drug or hypoglycemic drug) containing the obtained substance as an active ingredient.

As examples, a substance having an action for lowering blood pressure, a substance having an analgesic action or a substance having an action for lowering blood sugar level will be described below in this order. However, any substances fall within the scope of the present invention so long as they are obtained by utilizing a screening system using the animal of the present invention.

1. Method for Screening for Substance Having Action for Lowering Blood Pressure (Hypotensive Drug)

Candidate substances can be screened for a substance having an action for lowering blood pressure through blocking the influx of Ca²⁺ passed through N-type Ca channel by administering each of the candidate substances to a non-human animal deficient in the N-type Ca channel (N-KO animal) and a wild-type animal not deficient in the channel (Wt animal) and selecting a drug that lowers blood pressure in the Wt animal, but not in the N-KO animal.

Further, on the contrary, candidate substances can be screened for a substance having an action for lowering blood pressure without blocking the influx of Ca²⁺ passed through the N-type Ca channel by selecting a substance having an action for lowering blood pressure in the N-KO animal. Although the N-KO mouse of the present invention had been expected to be deficient in blood pressure control through nervous systems, the average blood pressure of the N-KO mice was higher than that of the wt animals and this suggested that a blood pressure control system through an endogenous factor intensely operated in the N-KO animal. Therefore, the N—RO animal is particularly useful for screening for a substance having an action for lowering blood pressure through an endogenous factor.

Specifically, for example, when an N-KO mouse and a wild-type mouse (hereinafter, referred to as Wt mouse) are used, following anesthetization of each mouse, a tube is placed in the trachea and artificial respiration is attained by using an animal ventilator with air ventilation of 0.2 ml at a respiratory frequency of 140 breaths/min. A polyethylene tube filled with a physiological saline containing heparin is inserted into the right common carotid artery and connected to a pressure transducer to measure the blood pressure. Each of candidate substances to be subjected to the screening is administered by using an indwelling catheter placed in the left common carotid artery, and a substance having an action for lowering the blood pressure is selected from the candidates.

2. Method for Screening for Substance Having Analgesic Action (Analgesic Drug)

Candidate substances can be screened for a substance having an analgesic action through or not through blocking of the influx of Ca²⁺ passed through N-type Ca channel by administering the candidate substances to an N-KO animal and a Wt animal and comparing their analgesic actions. The analgesic action can be confirmed by, for example, a formalin test, hot-plate test, acetic acid-induced writhing test, tail-flick test, tail-pinch test or the like.

Specifically, for example, in the case of a formalin test using an N-KO mouse and a Wt mouse, 20 μl of 3% formalin is subcutaneously administered to each of the N-KO mouse and the Wt mouse at the sole of the left hind leg. Then, the duration of the mouse's behavior of licking its left hind leg (licking) was measured over 30 minutes for use as an indicator of pain. Substances subjected to the screening are administered, and a substance reducing the pain indicator can be selected.

3. Method for Screening for Substance Having Action for Lowering Blood Sugar Level (Hypoglycemic Drug)

Candidate substances can be screened for a substance having a hypoglycemic action through or not through blocking of the influx of Ca²⁺ passed through N-type Ca channel by administering each of the candidate substances to an N-KO animal and a wt animal and comparing their hypoglycemic actions.

Specifically, for example, when an N-KO mouse and a Wt mouse are used, blood is collected from the caudal vein of each of the N-KO mouse and the Wt mouse under a fed condition (fasted for 2 hours prior to blood collection) or a fasted condition (fasted for 18 hours) and the blood sugar level is measured. The blood sugar level can be measured, for example, as follows. 10 μl of blood and 90 μl of 0.6 N perchloric acid are mixed and subjected to centrifugation (7,000 rpm, 2 min). Then, 20 μl of the supernatant and 300 μl of color developing solution of Glucose CII-Test Wako (Wako Pure Chemical Industries) are mixed and allowed to react at 37° C. for 5 minutes, and absorption of the reaction mixture is measured at 505 nm.

A drug containing a substance having a pharmacological action as an active ingredient can be manufactured according to a usual drug preparation method. The drug may be a pharmaceutical composition of a substance having a pharmacological action and a pharmaceutically acceptable carrier.

EXAMPLES

The present invention will be explained more specifically with reference to the following examples. However, the scope of the present invention is not limited to these examples.

Example 1 Disruption of Gene Coding for N-type Ca Channel by Gene Targeting

(1) Cloning of Gene Coding for N-type Ca Channel α_(1B) Subunit

Primers (SEQ ID NOS: 4 and 5) were designed based on the nucleotide sequence of the mouse α_(1B) subunit gene described in FEBS Letters, 338, pp. 1–5, 1994, and PCR was performed by using the mouse cDNA library as a template to obtain DNA having the nucleotide sequence of SEQ ID NO: 6. By using this DNA as a probe, a phage DNA clone with a part of the gene coding for the N-type Ca channel α_(1B) subunit was isolated from a 129SVJ-derived mouse genomic library (λFIXII). The restriction enzyme map of the obtained phage DNA clone is shown in FIG. 1.

(2) Construction of Targeting Vector

A targeting vector was prepared by a method wherein a region including exon B in the α_(1B) subunit gene was used as a homologous gene region; a neomycin resistance gene was introduced into the exon B (FIG. 1), and the thymidine kinase gene of herpes simplex virus was introduced as a negative selection gene (Suzanne, L. et al., Nature, 336, p. 348, 1988).

Outline of the construction is shown in FIGS. 2–4. The phage DNA clone obtained in (1) was digested with BamHI and subcloned into pBluescript II SK+ to obtain pBS59 and pBS58 having the fragments shown in FIGS. 2 and 3. The phage DNA clone was also digested with HindIII and subcloned into pBluescript II SK+ to obtain pBS63 having a fragment shown in FIG. 2. The pBS59 was digested with AatII and EcoRI and a fragment excised from pBS63 with AatII and HindIII was introduced thereto to obtain pBS59/63. This pBS59/63 was digested with AatII and a fragment including the neomycin resistance gene was introduced thereto to prepare pBS59/63n. This was further digested with EcoRV and a fragment excised from pBS58 with EcoRV wa introduced thereto to prepare pBS59/63/58n. The thymidine kinase gene, which is a selection gene, was introduced into the SalI-XhoI site of a multicloning site in pBS59/63/58n to produce a targeting vector.

(3) Acquisition of Embryonic Stem Cell (ES Cell) Having Undergone Homologous Recombination

The targeting vector obtained in (2) was digested with NotI to form linear DNA (1 mg/ml). As a mouse ES cell, TT2 was used (Yagi, T. et al., Analytical Biochem. 214, p. 70, 1993). The linear targeting vector (200 μg/ml) was transfected into the ES cells (1×10⁷ cells/ml) by electroporation (250 V, 975 μF, room temperature), and the cells were cultured in a medium containing G418 (250 μg/ml) and ganciclovir (0.2 μM) for 3 days from day 2 of culture, and then cultured in a medium containing G418 (250 μg/ml) for 3 days. DNA was extracted from a part of the generated ES cell colonies, and PCR was performed by using this DNA as a template, and DNA having the nucleotide sequence (SEQ ID NO: 7) outside the targeting vector and DNA having the nucleotide sequence (SEQ ID NO: 8) included in the introduced gene (neomycin resistance gene) as primers. Clones generating 3.7-kb PCR product were assumed as candidates that have possibility of having undergone homologous recombination.

Among the candidate clones, a clone having undergone only homologous recombination was identified by Southern blotting analysis. The extracted genome was digested with ApaLI and BalI, hybridized with a probe Pro9P outside the targeting vector (about 0.9-kbp DNA 5′-upstream from the homologously recombined region was obtained by PCR, see FIG. 1) and a probe Pro8 inside the targeting vector (about 0.8-kbp DNA excised from pBS59 with SphI and BamHI, see FIG. 1). A clone having undergone homologous recombination was selected, that is, a clone was selected for which a 6.9-kb band was detected in the ApaL1 digestion product and a 4.6-kb band was detected in the BalI digestion product when Pro9P was used as a probe, while a 6.9-kb band was detected in the ApaL1 digestion product and a 2.4-kb band was detected in the BalI digestion product when Pro8 was used as a probe.

(4) Preparation of N-KO Mouse

To a female mouse, 5 IU of pregnant mare's serum gonadotropin (PMSG, Serotropin, Teikoku Hormone Mfg., Tokyo) and 2.5 IU of human chorionic gonadotropin (hCG, Gonatropin, Teikoku Hormone Mfg., Tokyo) were intraperitoneally administered. On day 2.5 after fertilization, an 8-cell embryo was obtained by the oviduct-uterus perfusion method.

To the 8-cell embryo, the ES cells having undergone homologous recombination obtained in (3) were microinjected under an inverted microscope (DIAPHOTO TMD, Nippon Kogaku Kogyo, Tokyo) by using a micromanipulator (coarse-adjustment electric manipulator equipped with a suspended type joystick three-dimensional oil hydraulic micromanipulator, Narishige, Tokyo), a microinjector (Narishige, Tokyo), an injection pipette and a holding pipette. Further, as an injection dish., there were used several 5-μl medium droplets containing floating ES cells formed on Falcon 3002 (Becton Dickinson Labware) and overlaid with liquid paraffin.

Vasoligated male mice and normal female mice were mated to prepare pseudopregnant mice, and manipulated eggs into which three different ES cell clones having undergone homologous recombination were microinjected were implanted in the pseudopregnant mice. The pseudopregnant mice were generally anesthetized with 50 mg/kg body weight of pentobarbital sodium (Nembutal, Abbott Laboratories). Then, both flanks were incised about 1 cm to expose the ovary and the oviduct. The bursa ovarica was incised by using tweezers under a stereoscopic microscope to expose the fimbriae tubae. Subsequently, 7 to 8 manipulated eggs per oviduct were transferred into the fimbriae tubae. Then, the oviduct and the ovary were returned to the abdominal cavity, and both the incision sites were sutured.

The mice in which the manipulated eggs were implanted to be pregnant delivered a 100% chimeric mouse with a black coat color. To confirm that germ cells of the obtained 100% chimeric mouse were derived from the ES cells, the chimeric mouse was mated with an ICR female mouse, and their offspring mice were examined. The coat color of all the offspring mice was black, and hence it was confirmed that the germ cells of the chimeric mouse were derived from the ES cells. He mice were obtained by mating the chimeric mouse with C57BL/6, and an N-KO mouse was obtained by mating He mice with each other.

The genotypes of the obtained mice were confirmed based on differences in size of DNA fragments generated by PCR. The tail of each mouse was excised in a length of about 2–3 mm and digested (55° C., 2 hours) with a proteinase K solution (lysis buffer (Perkin Elmer) was diluted two-fold with PBS(−), 1% mercaptoethanol, 0.25 mg/ml of proteinase K). Thereafter, genomic DNA was extracted by a usual method and dissolved in 100–200 μl of distilled water to prepare a template for PCR. Primers were designed for the sequence included in the neomycin resistance gene (SEQ ID NO: 8) and two sites in the α_(1B) subunit gene (SEQ ID NOS: 9 and 10), and PCR was performed to identify the genotype of each individual. The gene having undergone a mutation produced a 520-bp PCR product, whereas the wild-type gene produced a 490-bp PCR product.

As required, the genotype was also confirmed by Southern blotting analysis. When the genomic DNA extracted from the mouse tail was digested with BamHI, and a region adjacent to the neomycin resistance gene in the targeting vector was hybridized with a probe ProN (about 1-kbp DNA excised from pBS59 with NcoI, see FIG. 1), only a 3.1-kb band was detected for the N-KO mouse.

The expression amount of mRNA in mouse brain was confirmed by Northern blotting. Total RNA was extracted from each of brains of 3 mice having each genotype by the AGPC method. Purified mRNA was obtained from the total RNA by using an oligo dT column (Amersham Pharmacia Biotech). The mRNA (5 μg/lane) was subjected to electrophoresis on 0.5% gel and hybridized with DNA having the nucleotide sequence of SEQ ID NO: 6 as a probe. The Northern blotting analysis showed that the mRNA expressed in the Wt mouse had completely disappeared in the N-KO mouse.

(5) Confirmation of N-KO Based on Electric Current Passed Through N-type Ca Channel

By using nerve cells in the dorsal root ganglia of the Wt mouse and the N-KO mouse, changes in the amount of Ca²⁺ influx inhibited by the ω-conotoxin GVIA were measured by using Ba²⁺ as a charge carrier by the whole-cell patch clamp method.

A 5- to 8-week old mouse was anesthetized with ether, and its dorsal root ganglia were removed and digested in a Krebs solution by using pronase (0.2 mg/ml) first for 30 minutes and then thermolysin (0.2 mg/ml) for 30 minutes to isolate cells.

A patch clamp amplifier (Axopatch 200B) was set at a whole cell mode, and measurement was performed at room temperature. A patch pipette (outer diameter: 1.5 mm, inner diameter: 1.1 mm) was prepared by using a P-87 Flaming-Brown micropipette puller (Sutter Instrument). A solution containing 3 mM BaCl₂, 155 mM tetraethylammonium chloride, 10 mM HEPES and 10 mM glucose (pH 7.4) was used as the outer solution of the isolated nerve cells and the patch pipette was filled with a solution containing 85 mM cesium aspartate, 40 mM CsCl, 2 mM MgCl₂, 5 mM EGTA, 2 mM ATPMg, 5 mM HEPES and 10 mM creatine phosphate (pH 7.4). The electric resistance of the pipette was 1–2 Mohm, and the current of Ba²⁺ obtained by a stimulus at 100 kHz was analyzed by using pCLAMP (Axon Instruments). The currents of the total Ca channels of nerve cells were measured for the Wt mouse and the N-KO, and the ω-conotoxin GVIA (1 μM) was added to measure the current other than that for N-type Ca channel.

The results are shown in FIG. 5. The values in the figure are average values, and the bars represent standard deviations (Wt (+/+): n=4, N-KO (−/−): n=7). It was electrophysiologically proved that the influx of Ca²⁺ inhibited by the ω-conotoxin GVIA was not observed in nerve cells of the nerve dorsal root ganglia extracted from the N-KO mouser and thus it was confirmed that the N-KO mouse lacked functional N-type Ca channel.

(6) Comparison of Body Weight, Heart Rate and Blood Pressure Between Genotypes

Body weight, heart rate and average blood pressure of a Wt mouse and those of an N-KO mouse were compared and examined. The Wt mice (15- to 16-week old, male, n=4) and the N-KO mice (15- to 16-week old, male, n=4) were anesthetized with 10% urethane. Following tracheal intubation, artificial respiration was performed by using an animal ventilator (Columbs) with a ventilation volume of 0.2 ml at a respiratory frequency of 140 breaths/min. A polyethylene tube filled with physiological saline containing heparin was inserted into the right common carotid artery and connected to a pressure transducer (Millar, Model MPC-500) to measure the blood pressure. The heart rate was obtained from blood pressure pulsation.

The results are shown in FIG. 6. The values in the figure are average values, and the significant differences were determined by the t-test. There was no difference in body weight between the two groups (28.2±3.2 g vs. 30.8±4.0 g). The heart rate and the average blood pressure of the N-KO mice were significantly higher than those of the Wt mice (562±101.9 beats/min vs. 742±32.5 beats/min, p<0.05, 73.4±7.7 mmHg vs. 100.0±6.6 mmHg, p<0.05).

These results are considered to suggest a possibility that the heart rate and the blood pressure were maintained at a constant level due to vagotonia in the Wt mouse, whereas a vagotonia state was lost due to the lack of sympathetic innervation and parasympathetic innervation, and the heart rate and the blood pressure were significantly higher in the N-KO mouse. Further, it is also considered to be possible that the N-KO mouse constantly has higher levels of factors involved in the pressure rise such as nerve transmitter substances including noradrenaline, angiotensin II, endothelin etc.

Example 2 Changes in Blood Pressure Upon Administration of ω-Conotoxin GVIA to Mouse

Changes in heart rate and blood pressure of a Wt mouse and those of an N-KO mouse due to the ω-conotoxin GVIA were evaluated. Wt mice (15- to 16-week old, male, body weight 28.2±3.2 g, n=4) and N-KO mice (15- to 16-week old, male, body weight 30.8±4.0 g, n=4) were anesthetized with 10% urethane. Following tracheal intubation, artificial respiration was performed by using an animal ventilator (Columbs) with a ventilation volume of 0.2 ml at a respiratory frequency of 140 breaths/min. A polyethylene tube filled with physiological saline containing heparin was inserted into the right common carotid artery and connected to a pressure transducer (Millar, Model MPC-500) to measure the blood pressure. Further, a catheter was indwelled in the left common carotid artery to administer ω-conotoxin GVIA (omega-CgTx GVIA, 30 μg/kg).

The results are shown in FIG. 7. The values in the figure are average values, and the bars represent standard deviations. In the wt mice., significant decreases in the heart rate and the blood pressure were observed from 10 minutes after the administration. On the other hand, no changes in the heart rate and the blood pressure were observed in the N-KO mouse even after the administration of ω-conotoxin GVIA.

These results suggest that N-type Ca channel should be involved in the controls of heart rate and blood pressure. Therefore, it is considered that the N-KO mouse is an animal model useful for elucidating the control mechanisms of heart rate and blood pressure.

Example 3 Experiment about Blood Pressure Control Mechanism—Examination of Blood Pressure Change with Bilateral Carotid Occlusion

Blood pressure changes with bilateral carotid occlusion (henceforth referred to as BCO) in a Wt mouse and an N-KO mouse were evaluated. Wt mice (15- to 16-week old, male, body weight 28.2±3.2 g, n=4) and N-KO mice (15- to 16-week old, male, body weight 30.8±4.0 g, n=4) were anesthetized with 10% urethane. Following tracheal intubation, artificial respiration was performed by using an animal ventilator (Columbs) with a ventilation volume of 0.2 ml at a respiratory frequency of 140 breaths/minute. A polyethylene tube filled with physiological saline containing heparin was inserted into the right common carotid artery and connected to a pressure transducer (Millar, Model MPC-500) to measure the blood pressure. Further, a silk thread (Natsume, suture needle with thread, Black broad silk No. 8-0) for artery occlusion was placed on the left common carotid artery, and the blood flow was transiently stopped by holding the silk thread upward to obtain a BCO state.

As a result of BCO for 30 seconds, a transient rise of blood pressure was observed in the Wt mice, but this blood pressure rise mostly disappeared after the administration of ω-conotoxin GVIA (30 μg/kg). On the other hand, no blood pressure rise was observed in the N-KO mice even in the BCO state. Typical data are shown in FIG. 8 (upper lines: arterial pressure, lower lines: average blood pressure in FIG. 8).

From these results, it is considered that the N-KO mouse lacked a pressure reflex mechanism through a pressure receptor present in the internal carotid artery, and that nerve transmitter substances were not released at least from a neuroterminal of the sympathetic nerve postganglionic fiber.

It is considered that roles of Ca channel of each subtype at an autonomic neuroterminal involved in the cardiocirculatory control mechanism can be revealed by using the N-KO mouse.

Example 4 Examination of Analgesic Effect on Formalin Administration

In this experiment, a Wt mouse, He mouse and N-KO mouse (male, 6-week old) were used. 30 μl of formaldehyde solution (WAKO, 35.0–38.0%, first grade, Lot No. DLL4284) was added to 970 μl of physiological saline. This is referred to as 3% formalin. 20 μl of the 3% formalin was subcutaneously administered to the mouse at the sole of left hind leg. After the formalin was administered, the duration of the mouse's behavior of licking its left hind leg (licking) was measured over 30 minutes for use as an indicator of pain. The duration was summed up every 5 minutes and represented in seconds. The significant difference was obtained by performing a parametric one-way layout variance analysis and then Dunnet's multiple comparison test (*: p<0.05, **: p<0.01 vs. control group). In the test, a statistical analysis support system into which SAS 6.12 (SAS Institute Japan, Tokyo) was incorporated was used.

As a result, no difference was observed for pain in a first phase (0–5 minutes) in the N-KO mouse compared with the Wt mouse and the He mouse, but an analgesic effect was observed on pain in a second phase (15–30 minutes) (FIG. 9). This suggests that N-type Ca channel is involved in transmission of pain. It is also suggested that, since the transmission of pain is not completely suppressed, the N-KO mouse is useful for evaluation of analgesic drugs through action points other than N-type Ca channel.

Example 5 Blood Sugar Level of N-KO Mouse

1. Measurement of Blood Sugar Level of N-KO Mouse

10 μl of blood was collected from each caudal vein of N-KO mice and Wt mice (wt (+/+) male: n=9, Wt female: n=10, N-KO (−/−) male: n=10, N-KO female: n=10) under a fed condition (fasted for 2 hours prior to blood collection) or a fasted condition (fasted for 18 hours), mixed with 90 μl of 0.6 N perchloric acid and centrifuged (7,000 rpm, 2 min). 20 μl of the supernatant and 300 μl of a color developing solution of Glucose CII-Test Wako (wako Pure Chemical industries) were mixed on a 96-well microplate, and allowed to react at 37° C. for 5 minutes, and absorbance of the mixture was measured at 505 nm.

The results are shown in FIG. 10. The values in the figure are average values. In the case of the fed condition, the N-KO mice showed significantly low blood sugar levels compared with those of the Wt mice (t-test). On the other hand, under the fasted condition, no significant difference was observed between blood sugar levels of those mice.

These results show that blood sugar level can be raised by activation of nerve transmission through the N-type Ca channel and indicate that the N-type Ca channel should be involved in normalization of blood sugar level (maintenance of homeostasis).

2. Glucose Tolerance Test of N-KO Mouse

Wt mice and N-KO mice (male, 9- to 10-month old, Wt: n=9, N-KO: n=9 for determination of blood sugar level, Wt: n=8, N-KO: n=9 for determination of insulin level) that had fasted for 16 hours were orally administered with 2 g/kg body weight of 20% glucose solution, and 10 μl each of blood was collected from the caudal vein after 0, 0.5, 1, 2, 3 and 4 hours to measure blood sugar level by the same method as described above. Further, 10 μl of blood collected in the same manner was mixed with 10 μl of heparin-containing physiological saline and centrifuged, and then the insulin level in the supernatant was quantified by using an enzyme immunoassay kit (Morinaga Milk Industry Co., Ltd, Biochemical Research Laboratory). The blood sugar levels and the insulin levels are shown in FIGS. 11 and 12, respectively. In FIGS. 11 and 12, the values are average values, and the bars represent standard deviations.

As shown in FIG. 11, the fasting blood sugar levels of the N-KO mice were significantly lower than those of the wt mice, and the blood sugar levels changed within a significantly low value range even after glucose was administered. It was considered that the 9- to 10-month old Wt mice had age-related insulin resistance, whereas changes in the blood sugar levels of the N-KO mice were similar to those of young mice.

This difference was also shown in the insulin levels shown in FIG. 12, and the Wt mice maintained a high insulin concentration before and after the glucose administration, whereas the N-KO mouse showed a low insulin concentration, which returned to the level before the glucose administration after 1 hour. Further, the insulin levels of the Wt mice significantly varied depending on each individual.

These experimental results indicate that the N-KO mouse does not become insulin resistant easily, and N-type Ca channel is involved in insulin resistance and further indicate that activation of the N-type Ca channel is associated with normalization of blood sugar level.

Amounts of glucagon and leptin were also measured, but no difference was observed between the Wt mice and the N-KO mice.

3. Immunofluorescence Staining of Spleen

In order to further confirm the involvement of N-type Ca channel in insulin resistance, pancreatic β cells in islets of Langerhans of a Wt mouse and an N-KO mouse were compared.

A Wt mouse and an N-KO mouse (male, 11-month old) were anesthetized with Nembutal and subjected to abdominal section, then a portion around a valve of the right atrium was excised, and blood was removed. PBS containing heparin (4 U/ml) was injected from the left ventricle, and whitening of the liver was confirmed. Then, 4% paraformaldehyde dissolved in PBS was further injected. When rigor of each individual was confirmed, the pancreas was removed and fixed with 4% paraformaldehyde at 4° C. for 1 hour. Following the fixation, the pancreas was left overnight in PBS containing 30% sucrose at 4° C. and embedded in an OCT compound to prepare a thin section.

The thin section was stained by using a guinea pig anti-insulin serum (Linco Research) as primary antibodies and rhodamine-labeled anti-guinea pig IgG antibodies (Chemicon International) as secondary antibodies, and the β cells containing insulin were observed with a fluorescence microscope. Similarly, the thin section was stained by using rabbit anti-glucagon antibodies (Linco Research) and FITC-labeled anti-rabbit IgG antibodies (Organon Teknika), and the α cells containing glucagon were observed.

In the N-KO mouse, a cell aggregation of β cells was small, and an increase in the number of β cells with aging was not observed, which was observed in the Wt mouse. On the other hand, no difference was observed in a cells between the both mice.

It is considered that the wt mouse had age-related insulin resistance and insulin production in β cells was accelerated, while the N-KO mouse did not have insulin resistance.

Example 6 Autonomic Innervation of Atrial Muscle Contractile Force of N-KO Mouse

Autonomic innervation of atrial muscle contractile force of an N-KO mouse was examined. The atriums were isolated from mice (Wt mice and N-KO mice: n=5 each), and the contractile force and the action potential were simultaneously recorded by giving a direct muscle stimulus and a nerve stimulus from two of stimulators. As for stimulus conditions, the basal stimulus was given with a frequency of 2 Hz, a voltage just above the threshold and a pulse width of 1 msec. The nerve stimulus was given with a frequency of 200 Hz, a voltage 1.5 times as high as the basal stimulus and a pulse width of 0.1 msec. Four nerve stimuli per basal stimulus were given during a refractory period of the cardiac muscle, which lasted 15 seconds.

FIG. 13 shows experimental results in the left atrium and the right atrium of 5 cases. The values are average values, and the bars represent standard deviations. In the figure, w-CgTx represents ω-conotoxin GVIA.

In the left atrium, the atrial muscle contractile force of the Wt mouse was greatly increased by the nerve stimulus in the presence of atropine, and this increase in the contractile force was almost completely inhibited by 30 nM ω-conotoxin GVIA. On the other hand, although a slight increase was observed in the atrial muscle contractile force of the N-KO mouse by the nerve stimulus in the presence of atropine, this increase in the contractile force was not suppressed by the ω-conotoxin GVIA up to 100 nM. These increases in the contractile force were completely inhibited by 0.1 μM tetrodotoxin, although the data are not shown in the figure.

Although no increase in the contractile force of the atrial muscle caused by the atropine nerve stimulus was not so remarkable in the right atrial muscle as in the left atrium, the obtained result was almost similar to that of the left atrium.

These results are considered to suggest that the release of norepinephrine (NE) from the sympathetic nerve mostly depended on N-type Ca channel in the Wt mouse, but Ca channels of other types were increased in a compensatory manner and contributed to the release of NE in the N-KO mouse. In the Wt mouse, it is expected that an increase in the contractile force by a nerve stimulus in the right atrium is smaller than that in the left atrium and hence there is a difference in innervation densities in the left and right atriums.

INDUSTRIAL APPLICABILITY

The present invention provides an animal that does not show a functional expression of N-type Ca channel By using the animal of the present invention, the function of the N-type Ca channel can be deduced. Further, by administrating a drug to an N-KO animal and a wt animal, whether the drug acts on the N-type Ca channel can be deduced from the difference in their responses. Furthermore, there are provided a method for screening for a substance having a pharmacological action on blood pressure control, transmission of pain, blood sugar level control and so forth by using the animal of the present invention, a substance having a pharmacological action obtained by the screening method and a method for manufacturing a drug comprising screening for a substance having a pharmacological action by the screening method and manufacturing a drug comprising the obtained substance as an active ingredient. 

1. A transgenic mouse in which a gene coding for the α_(1B) subunit of the N-type calcium channel is disrupted so that the mouse lacks the functional α_(1B) subunit of the N-type calcium channel, wherein said disruption results in an increased heart rate and blood pressure, decreased transmission of second phase pain or decreased insulin and glucose levels after feeding.
 2. The transgenic mouse according to claim 1, wherein the gene comprises DNA defined in the following (a) or (b): (a) DNA which comprises the nucleotide sequence of SEQ ID NO: 1; (b) DNA which hybridizes with DNA comprising the nucleotide sequence of SEQ ID NO: 1 under a stringent condition of hybridization at 65° C. in 4×SSC and subsequent washing at 65° C. in 0.1×SSC for 1 hour and codes for the functional α_(1B) subunit of the N-type calcium channel.
 3. A method for screening for a substance having a pharmacological action, which comprises a step of determining pharmacological action of the substance by the method of (a) or (b): (a) a method which comprises steps of administering a substance to the transgenic mouse as defined in claim 1 and determining the pharmacological action of the substance, or (b) a method which comprises steps of administering a substance to the transgenic mouse as defined in claim 1 and a wild-type mouse, and comparing the pharmacological actions of the substance on the transgenic mouse and the wild-type mouse to determine the pharmacological action of the substance, wherein the pharmacological action is an action for lowering blood pressure, an analgesic action, or an action for lowering blood sugar level.
 4. A method for manufacturing a pharmaceutical composition, which comprises steps of screening for a substance having a pharmacological action by the method as defined in claim 3 to obtain a substance having an action for lowering blood pressure an analgesic action, or an action for lowering blood sugar level, and mixing the obtained substance with a pharmaceutically acceptable carrier to manufacture a pharmaceutical composition comprising the obtained substance as an active ingredient.
 5. The method according to claim 3, wherein the pharmacological action is an action for lowering blood pressure.
 6. The method according to claim 3, wherein the pharmacological action is an analgesic action.
 7. The method according to claim 3, wherein the pharmacological action is an action for lowering blood sugar level. 